Mop bucket system with wave reduction capability

ABSTRACT

A mop bucket system includes a liquid-retaining portion and an energy-dissipation device. The liquid-retaining portion is configured to retain liquid. It has a bottom wall portion, a first sidewall portion, a second sidewall portion facing the first sidewall portion, a third sidewall portion, and a fourth sidewall portion facing the third sidewall portion. The liquid-retaining portion permits retained liquid to move in a liquid-movement direction extending from the first sidewall portion toward the second sidewall portion within a higher-momentum region having a width that is approximately 70% of a distance between the third sidewall portion and the fourth sidewall portion. The energy-dissipation device is disposed within the liquid-retaining portion and extends into the higher-momentum region. The energy-dissipation device being configured to inhibit build up of momentum of liquid in the higher-momentum region along at least a portion of the liquid-movement direction by breaking surface tension of the liquid.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Application Nos.60/610,206 (filed Sep. 16, 2004) and 60/618,175 (filed Oct. 14, 2004),which are incorporated herein by reference in their entirety.

BACKGROUND

Mop bucket systems are commonly used for cleaning purposes. A mop bucketcontains liquid used for cleaning. It is typically used to facilitatethe mopping of floors.

With a conventional mop bucket, cleaning liquid may spill or splashduring use. For example, often the mop bucket and cleaning liquid mustbe moved from one location to another. During this movement, the mopbucket will be subjected to differing Newtonian forces. The mop bucketwill experience a starting force as it is initially accelerated towardthe next location and will experience a stopping force when it reachesthat location and is decelerated. Also, while the bucket is being moved,it may experience instantaneous turbulent forces at the interfacebetween the liquid and air, sometimes called wave amplification orripples. The changing forces on the mop bucket will cause the cleaningliquid to be displaced relative to the mop bucket. The displacement ofthe cleaning liquid can result in the formation of a wave that splashesover the top of a wall of the mop bucket and out onto a floor orstairway. Also, the amplification of these waves due to the high degreeof turbulence may also cause splashing and liquid droplets to exit themop bucket.

Spillage of the cleaning liquid is problematic. For example, cleaningliquid that has spilled out of the mop bucket onto a floor or stairwaycreate a slip-and-fall hazard if not immediately removed. Even if theliquid is immediately removed, non-productive man hours are required toclean the spill. Spillage also is inefficient and undesirable because itcan result in the loss of cleaning liquid.

It would be desirable to have a mop bucket system that reduces thespillage of cleaning liquid.

SUMMARY

An aspect of the present invention relates to a mop bucket systemincluding a liquid-retaining portion and an energy-dissipation device.The liquid-retaining portion is configured to retain liquid. It has abottom wall portion, a first sidewall portion, a second sidewall portionfacing the first sidewall portion, a third sidewall portion, and afourth sidewall portion facing the third sidewall portion. Theliquid-retaining portion permits retained liquid to move in aliquid-movement direction extending from the first sidewall portiontoward the second sidewall portion within a higher-momentum regionhaving a width that is approximately 70% of a distance between the thirdsidewall portion and the fourth sidewall portion. The energy-dissipationdevice is disposed within the liquid-retaining portion and extends intothe higher-momentum region. The energy-dissipation device is configuredto inhibit build up of momentum of liquid in the higher-momentum regionalong at least a portion of the liquid-movement direction by breakingsurface tension of the liquid.

It is to be understood that both the foregoing general description andthe following detailed description are merely exemplary of theinvention, and are intended to provide an overview or framework forunderstanding the nature and character of the invention as it isclaimed. The accompanying drawings are included to provide a furtherunderstanding of the invention, and are incorporated in and constitute apart of this specification. The drawings illustrate various embodimentsof the invention, and together with the description serve to explain theprinciples and operation of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front perspective view of a first embodiment of a mop bucketsystem according to the present invention;

FIG. 2 is a front perspective view of the mop bucket system of FIG. 1;

FIG. 3 is a side, cross-sectional view of the mop bucket system of FIG.1;

FIG. 4 is a plan view of the mop bucket system of FIG. 1;

FIG. 5 is side, perspective view of the mop bucket system of FIG. 1;

FIG. 6 is a rear, perspective view of a second embodiment of a mopbucket system according to the present invention;

FIG. 7 is graph showing data from a simulation comparing the performanceof mop bucket systems at one-quarter of full capacity;

FIG. 8 is graph showing data from a simulation comparing the performanceof mop bucket systems at one-quarter of full capacity;

FIG. 9 is graph showing data from a simulation comparing the performanceof mop bucket systems at one-half of full capacity; and

FIG. 10 is graph showing data from a simulation comparing theperformance of mop bucket systems at one-half of full capacity.

DETAILED DESCRIPTION

Presently preferred embodiments of the invention are illustrated in thedrawings. An effort has been made to use the same or like referencenumbers throughout the drawings to refer to the same or like parts.

A first embodiment of a mop bucket system 10 according to the presentinvention is shown in FIGS. 1-5. The mop bucket system 10 includes aliquid-retaining portion 20 and an energy-dissipation device 50. The mopbucket system 10 also can include a wringer 33 and a bucket 34 forreceiving dirty water from the wringer 33.

A mop bucket 11 can provide the liquid-retaining portion 20, which isconfigured to retain liquid, such as cleaning liquid used to mop floors.Though not as preferred, the liquid-retaining portion 20 could beprovided by other container structures, such as drinking cups or mugs,if intended for use in systems other than a mop bucket system. As shownin FIG. 4, the liquid-retaining portion 20 includes a bottom wallportion 21, a first sidewall portion 22, a second sidewall portion 23facing the first sidewall portion 22, a third sidewall portion 24, and afourth sidewall portion 25 facing the third sidewall portion 24. Thesidewall portions 22, 23, 24, 25 can be connected in a variety of forms.For example, they can be portions of a rounded sidewall with no cleardemarcations between the sidewall portions (see, for example, theconnection between sidewall portions 22 and 24) or they can be connectedby distinct corners or edges that provide clear demarcations between thesidewall portions (see, for example, the connection between sidewallportions 23 and 24).

The sidewall portions 22, 23, 24, 25 can have approximately the sameheight. It is more preferred, however, that the first sidewall portion22 be shorter than the second sidewall portion 23. As shown in FIG. 3,in this preferred embodiment, the first sidewall portion 22 has a heightH1 of approximately 12 inches (more preferably 11.98 inches) and thesecond sidewall portion 23 has a height H2 of approximately 15 inches(more preferably 14.73 inches). The height of the third and fourthsidewall portions 24, 25 tapers between the heights of the first andsecond sidewall portions 22, 23.

When the mop bucket system 10 is subjected to differing forces, liquidwill be displaced relative to the liquid-retaining portion 20. Forexample, if the mop bucket system 10 is moved in the direction of thearrow A shown in FIG. 3, the liquid (not shown) will move in an oppositedirection relative to the liquid-retaining portion 20, i.e., in aliquid-movement direction extending from the first sidewall portion 22toward the second sidewall portion 23.

Within the liquid-retaining portion 20, the displacement of the liquidwill not be evenly distributed. As the liquid-retaining portion 20 stopsor starts, the energy of the liquid at the center is greater than alongthe third and fourth sidewall portions 24, 25, because of the no-slipboundary condition, i.e., forces along the third and fourth sidewallportions 24, 25 will slow the movement of the liquid near those sidewallportions. Consequently, a higher-momentum region will exist in theliquid. For the purpose of defining a location for elements of theenergy-dissipation device 50, as explained further below, boundaries ofthe higher-momentum region have been established by showing dashed lines27 in FIG. 4, which have a width W1 between them. Thus, the location ofthe dashed lines 27 and the corresponding width W1 are not intended tonecessarily require any specific attribute with regard to the energy orvelocity of the liquid. The width W1 preferably is approximately 70% ofa distance W2 between the third and fourth sidewall portions 24, 25,though W1 could be redefined as, for example, approximately 65%, 50%, or30% of the distance W2, depending on the preferred implementation andgoals to be achieved. In this preferred embodiment, the higher-momentumregion has a center that coincides with the center of theliquid-retaining portion 20.

As shown in FIGS. 1 and 2, the mop bucket system 10 may have rollingmembers 30, such as casters, to facilitate movement of the mop bucketsystem 10. The rolling members 30 preferably are connected to a dolly31, which receives the liquid-retaining portion 20, as shown in theexploded view of FIG. 2. Alternatively, the rolling members can bedirectly connected to the bottom of the liquid-retaining portion 20. Asyet another alternative, the rolling members can be omitted and the mopbucket system 10 could be moved from location to location by carryingthe mop bucket system 10.

The energy-dissipation device 50 is disposed within the liquid-retainingportion 20 and extends into the higher-momentum region between thedashed lines 27. The energy-dissipation device 50 can be configured toinhibit build up of momentum of liquid in the higher-momentum region andinhibit wave-amplification at the liquid surface region along at least aportion of the liquid-movement direction by breaking surface tension ofthe liquid. Under ideal operating conditions, the energy-dissipationdevice extends above the liquid surface.

The energy-dissipation device 50 can include a first baffle 52 and/or asecond baffle 54 disposed between the first and second sidewall portions22, 23 and within the higher-momentum region. The first and secondbaffles 52, 54 can be generally planar members that inhibit the flow ofliquid. In the disclosed embodiment, the first baffle 52 projects fromthe third sidewall portion 24 and the second baffle 54 projects from thefourth sidewall portion 25. Preferably, the first and second baffles 52,54 each project a distance W3 (see FIG. 4) of approximately 2.5 inches(more preferably 2.56 inches) from their respective sidewall portions24, 25. Preferably the width W3 of a respective baffle 52, 54 is atleast approximately 20% of distance W2, more preferably at leastapproximately 25%, and even more preferably at least approximately 35%.The length of each baffle is preferably less than its width W3, suchthat the baffle displaces only a small amount of liquid, while providingthe desired functionality. It is preferred that the baffles 52, 54project from their respective sidewall portions 24,25, but they could bespaced, i.e., disposed at a distance, from the sidewall portions.

The first and second baffles 52, 54 are located approximately midwaybetween the first and second sidewall portions 22, 23. This positioningcan inhibit build up of momentum of liquid at a location where thehighest liquid velocities can occur.

The height of the baffles 52, 54 (and other members that form theenergy-dissipation device 50) preferably is configured to extend abovethe expected liquid-fill height during normal use. Otherwise, if theliquid extends over the baffles 52, 54, they will not break the surfacetension of the liquid and their effectiveness will be reduced.Consequently, the first and second baffles 52, 54 preferably extend to aheight H3 (see FIG. 3) above a corresponding portion of the bottom wallthat is at least 25% (more preferably at least 40%, even more preferablyat least 50%, and even more preferably at least 55%) of the height of ashortest of the first, second, third, and fourth sidewall portions 22,23, 24, 25. The height H3 could be 100% of the height of a shortest ofthe first, second, third, and fourth sidewall portions 22, 23, 24, 25.In this preferred embodiment, the height H3 preferably is approximately7 inches (more preferably 6.70 inches).

The baffles 52, 54 can be configured to stop waves before they build upenergy or significantly reduce that energy buildup by creatingre-circulation zones. The baffles 52, 54 also force the liquid to travelthrough a resulting gap between the baffles 52, 54, thereby preventingenergy buildup through the entire domain. The baffles 52, 54 not onlybreak the surface tension of the liquid, they also can act as stopbarriers within the flow. As liquid strikes the baffles 52, 54, theability of the liquid to retain energy is diminished. Although there isan increased velocity within the gap between the baffles 52, 54,re-circulation zones on each side of the baffles 52, 54 allow the energyto dissipate more quickly than without the baffles 52, 54.

The energy-dissipation device 50 can include projections 56 from thesecond sidewall portion 23 that are disposed within the higher-momentumregion. The projections 56 can be configured to distribute energy fromretained liquid over a surface of the second sidewall portion 23.Preferably, the projections 56 increase in width W4 (see FIG. 4) in adirection from the first sidewall portion 22 toward the second sidewallportion 23. Even more preferably, the projections 56 provide asubstantially sinusoidal surface along the second sidewall portion 23.In this preferred embodiment, the projections taper to a largest widthW4 of approximately 2 inches (more preferably 1.94 inches) and project adistance W5 of at least approximately 1 inch (more preferably 1.12inches) toward the first sidewall portion 22. The projections can extendto a height above the bottom wall that is at least 25% (more preferablyat least 40% and even more preferably at least 50%) of the height of ashortest of the first, second, third, and fourth sidewall portions. Inthis preferred embodiment, the projections 56 extend along the entireheight H2 of the second sidewall portion 23.

The projections 56 from the second sidewall portion 23 allow the energyof the liquid to be effectively distributed over a larger surface area.Thus, as the liquid oscillates in the liquid-retaining portion 20, waveamplification is reduced, which minimizes splashing.

The energy-dissipation device 50 can include wedges 60 on the firstsidewall portion 22 that are disposed within the higher-momentum region.The wedges 60 project a distance W6 (see FIG. 3) toward the secondsidewall portion that is at least approximately 0.1 inches (morepreferably 0.11 inches) and have a width W7 (see FIG. 4) that is atleast approximately 1.5 inches (more preferably 1.52 inches). The wedges60 extend to a height H4 above a corresponding portion of the bottomwall that is at least 25% (more preferably at least 40% and even morepreferably at least 50%) of the height of a shortest of the first,second, third, and fourth sidewall portions. In this preferredembodiment, the height H4 is approximately 9 inches (more preferably8.67 inches).

In this preferred embodiment, the elements of the energy-dissipationdevice 50, i.e., baffles 52, 54, projections 56, and wedges 60, disposedwithin the liquid-retaining portion 20 are shown as integral with themop bucket 11. Though this is preferred, it is not required. Forexample, those elements of the energy-dissipation device 50 could beformed of structure(s) that are not integrally formed with the mopbucket 11 but instead are connected to the mop bucket 11 or merelyplaced within the mop bucket 11 without being fixed to it. As a morespecific example, a baffle could be connected to only the wringer 33 andextend downward from the wringer 33 into the higher-momentum region.

A second embodiment of a mop bucket system 110 according to the presentinvention is shown in FIG. 6. The mop bucket system 110 is the same asmop bucket system 10, except it does not include the baffles 52, 54.

The theoretical performances of a conventional bucket (RubbermaidCommercial Products Bucket #7570), the bucket of the first embodiment,and the bucket of the second embodiment (no baffles) were compared usingcomputational fluid dynamics (CFD). The commercially available codeFlow-3D® was utilized in the simulations.

The performance of the mop bucket systems was simulated to determine,among other things, the amount of liquid leaving the buckets. Theinstantaneous and total amounts of liquid leaving the mop bucket systemsat any given time permits quantification of the actual performance ofmop bucket systems in reducing splashing. To computationally measurethis quantity, a simulation was constructed in which a planar field wasplaced at the top of each mop bucket and, for any quantity of liquidcrossing this plane, the volume of liquid was tracked and recorded. Themop bucket system performances were simulated at approximatelyone-quarter of full capacity and at approximately one-half of fullcapacity.

FIGS. 7 and 9 show the instantaneous volumes of liquid leaving each ofthe buckets at one-quarter of full capacity and one-half of fullcapacity, respectively. FIGS. 8 and 10 represent the total volumes ofliquid that left each bucket at each interval (sum of instantaneousliquid splashing events) at one-quarter of full capacity and one-half offull capacity, respectively. The total volumes of liquid that left eachof the mop bucket system configurations are reproduced in the tablebelow.

Second Conventional Embodiment First Bucket (No Baffles) EmbodimentTotal Volume of Liquid 0.00172 0.00131 0.00102 Leaving Bucket When(0.4543759) (0.3460654) (0.2668138) Tested at One-Quarter of FullCapacity m³ (gal.) Total Volume of Liquid 0.00295 0.00274 0.00253Leaving Bucket When (0.7793076) (0.7238314) (0.6683553) Tested atOne-Half of Full Capacity m³ (gal.)

From the figures and the table, it can be seen that for one-quarter fullcapacity, the mop bucket system of the first and second embodiments ofthe present invention outperform the conventional bucket approximately90-95% and 50% of the time, respectively. The mop bucket system of thefirst embodiment reduces splashing by 40% over the conventional bucket,and the mop bucket system of the second embodiment reduces splashing byas much as 19% over the conventional bucket. This reduction in splashingis believed to result from breaking the surface tension of the liquid,which prevents wave amplification.

For one-half capacity simulations, the mop bucket system of the firstembodiment again outperforms the conventional bucket, although theperformance is less predictable qualitatively. The mop bucket system ofthe first embodiment reduces splashing by 15% over the conventionalbucket and the mop bucket system of the second embodiment reducessplashing by 12% over the conventional bucket.

It will be apparent to those skilled in the art that variousmodifications and variations can be made to the present inventionwithout departing from the spirit and scope of the invention. Thus, itis intended that the present invention cover the modifications andvariations of this invention provided they come within the scope of theappended claims and their equivalents.

1. A mop bucket system comprising: a liquid-retaining portion configuredto retain liquid and having a bottom wall portion, a first sidewallportion, a second sidewall portion facing the first sidewall portion, athird sidewall portion, and a fourth sidewall portion facing the thirdsidewall portion, wherein the liquid-retaining portion permits retainedliquid to move in a liquid-movement direction extending from the firstsidewall portion toward the second sidewall portion within ahigher-momentum region having a width that is approximately 70% of adistance between the third sidewall portion and the fourth sidewallportion; and an energy-dissipation device disposed within theliquid-retaining portion and extending into the higher-momentum region,the energy-dissipation device being configured to inhibit build up ofmomentum of liquid in the higher-momentum region along at least aportion of the liquid-movement direction by breaking surface tension ofthe liquid, wherein the energy-dissipation device includes a firstbaffle and a second baffle each disposed between the first and secondsidewall portions and within the higher-momentum region, wherein thefirst baffle projects from the third sidewall portion and the secondbaffle projects from the fourth sidewall portion, and wherein the firstand second baffles each project such a distance from the respectivethird and fourth sidewall portions that the first and second baffles arediscontinuous in that the first and second baffles do not in combinationform a single, uniformly shaped baffle.
 2. The mop bucket system ofclaim 1, wherein the first baffle extends to a height above the bottomwall that is at least 25% of the height of a shortest of the first,second, third, and fourth sidewall portions.
 3. The mop bucket system ofclaim 1, wherein the first baffle extends to a height above the bottomwall that is at least 40% of the height of a shortest of the first,second, third, and fourth sidewall portions.
 4. The mop bucket system ofclaim 1, wherein the first baffle extends to a height above the bottomwall that is at least 50% of the height of a shortest of the first,second, third, and fourth sidewall portions.
 5. The mop bucket system ofclaim 1, wherein the first baffle has a width that is at leastapproximately 20% of a distance between the third and fourth sidewallportions.
 6. The mop bucket system of claim 1, wherein the first bafflehas a width that is at least approximately 25% of a distance between thethird and fourth sidewall portions.
 7. The mop bucket system of claim 1,wherein the first baffle has a width that is at least approximately 35%of a distance between the third and fourth sidewall portions.
 8. The mopbucket system of claim 1, wherein each of the first and second bafflesextends to a height above the bottom wall that is at least 25% of theheight of a shortest of the first, second, third, and fourth sidewallportions.
 9. The mop bucket system of claim 1, wherein each of the firstand second baffles extends to a height above the bottom wall that is atleast 40% of the height of a shortest of the first, second, third, andfourth sidewall portions.
 10. The mop bucket system of claim 1, whereineach of the first and second baffles extends to a height above thebottom wall that is at least 50% of the height of a shortest of thefirst, second, third, and fourth sidewall portions.
 11. The mop bucketsystem of claim 1, wherein each of the first and second baffles has awidth that is at least approximately 20% of a distance between the thirdand fourth sidewall portions.
 12. The mop bucket system of claim 1,wherein each of the first and second baffles has a width that is atleast approximately 25% of a distance between the third and fourthsidewall portions.
 13. The mop bucket system of claim 1, wherein each ofthe first and second baffles has a width that is at least approximately35% of a distance between the third and fourth sidewall portions. 14.The mop bucket system of claim 1, wherein the energy-dissipation deviceincludes projections from the second sidewall portion, wherein theprojections are disposed within the higher-momentum region.
 15. The mopbucket system of claim 14, wherein the projections are configured todistribute energy from retained liquid over a surface of the secondsidewall portion.
 16. The mop bucket system of claim 14, wherein theprojections increase in width in a direction from the first sidewallportion toward the second sidewall portion.
 17. The mop bucket system ofclaim 14, wherein the projections provide a substantially sinusoidalsurface along the second sidewall portion.
 18. The mop bucket system ofclaim 14, wherein the projections project at least one inch toward thefirst sidewall portion.
 19. The mop bucket system of claim 14, whereinthe projections extend to a height above the bottom wall that is atleast 25% of the height of a shortest of the first, second, third, andfourth sidewall portions.
 20. The mop bucket system of claim 14, whereinthe projections extend to a height above the bottom wall that is atleast 40% of the height of a shortest of the first, second, third, andfourth sidewall portions.
 21. The mop bucket system of claim 14, whereinthe projections extend to a height above the bottom wall that is atleast 50% of the height of a shortest of the first, second, third, andfourth sidewall portions.
 22. The mop bucket system of claim 1, whereinthe energy-dissipation device includes wedges on the second sidewallportion, wherein the wedges are disposed within the higher-momentumregion.
 23. The mop bucket system of claim 22, wherein the wedgesproject at least 0.1 inch toward the second sidewall portion.
 24. Themop bucket system of claim 22, wherein the wedges extend to a heightabove the bottom wall that is at least 25% of the height of a shortestof the first, second, third, and fourth sidewall portions.
 25. The mopbucket system of claim 22, wherein the wedges extend to a height abovethe bottom wall that is at least 40% of the height of a shortest of thefirst, second, third, and fourth sidewall portions.
 26. The mop bucketsystem of claim 22, wherein the wedges extend to a height above thebottom wall that is at least 50% of the height of a shortest of thefirst, second, third, and fourth sidewall portions.
 27. The mop bucketsystem of claim 1, further comprising rolling members connected to theliquid-retaining portion.